/* To insert an edge to the graph. */
void graph_using_AL::insert_edge(string from_v, string to_v) {
map<string, set<string> >::iterator from_temp_itr, to_temp_itr;
from_temp_itr = data.find(from_v);
to_temp_itr = data.find(to_v );
if(from_temp_itr == data.end()) {
if(debug_flag) clog << "From_node " << from_v << " not found" << endl;
/* Inserting. */
if(debug_flag) clog << "Inserting edge " << from_v << "-->" << to_v << endl;
set<string> temp_set;
temp_set.insert(to_v);
pair<string, set<string> > temp_pair(from_v, temp_set);
data.insert(temp_pair);
if(d_type == undirected_graph) {
if(to_temp_itr == data.end()) {
if(debug_flag) clog << "Inserting edge " << to_v << "-->" << from_v << endl;
temp_set.clear();
temp_set.insert(from_v);
pair<string, set<string> > temp_pair(to_v, temp_set);
data.insert(temp_pair);
}
else {
to_temp_itr->second.insert(from_v);
}
}
else {
/* It is a directed graph. */
if(to_temp_itr == data.end()) {
if(debug_flag) clog << to_v << " is a new entry. " << endl;
set<string> temp_set_2;
pair<string, set<string> > temp_pair_2(to_v, temp_set_2);
data.insert(temp_pair_2);
}
}
}
else {
/* From node found. */
if(debug_flag) clog << "From node " << from_v << " found" << endl;
if(debug_flag) clog << "Searching if " << to_v << " is found in " << from_temp_itr->first << endl;
set<string>::iterator itr = find(from_temp_itr->second.begin(), from_temp_itr->second.end(), to_v);
if(itr == from_temp_itr->second.end()) {
if(debug_flag) clog << "To node " << to_v << " not found" << endl;
if(debug_flag) clog << "Creating the edge " << from_v << "-->" << to_v << endl;
from_temp_itr->second.insert(to_v);
if(d_type == undirected_graph) {
if(debug_flag) clog << "Creating the edge " << to_v << "-->" << from_v << endl;
from_temp_itr = data.find(to_v);
if(from_temp_itr == data.end()) {
if(debug_flag) clog << to_v << " is a new entry. " << endl;
set<string> temp_set;
temp_set.insert(from_v);
pair<string, set<string> > temp_pair(to_v, temp_set);
data.insert(temp_pair);
}
else {
if(from_v != to_v) from_temp_itr->second.insert(from_v);
else if(debug_flag) clog << "loop" << endl;
}
}
}
else {
if(debug_flag) clog << "The edge is already present" << endl;
}
}
/* Setting the weight to 0 for weighted graphs. */
if(w_type == weighted_graph) {
if(d_type == undirected_graph)
set_weight(from_v, to_v, 0), set_weight(to_v, from_v, 0);
else
set_weight(from_v, to_v, 0);
}
if(debug_flag) print();
return;
}
// main k-mer counting function, shared between minia and dsk
// verbose == 0 : stderr progress bar
// verbose >= 1 : print basic status
// verbose >= 2 : print extra partition information
// write_count == True: include kmer count in results file, in that form:
// - save kmer count for each kmer in the resulting binary file
// - the very first four bytes of the result file are the kmer length
void sorting_count(Bank *Sequences, char *prefix, int max_memory, int max_disk_space, bool write_count, int verbose)
{
// create a temp dir from the prefix
char temp_dir[1024];
sprintf(temp_dir,"%s_temp",prefix);
// clear the temp folder (needs to be done before estimating disk space)
DIR* dp;
struct dirent* ep;
char p_buf[512] = {0};
dp = opendir(temp_dir);
while ( (dp != NULL) && ((ep = readdir(dp)) != NULL)) {
sprintf(p_buf, "%s/%s", temp_dir, ep->d_name);
remove(p_buf);
}
if(dp != NULL)
closedir(dp);
if (max_disk_space == 0)
{
// default max disk space
struct statvfs buffer ;
char current_path[1000];
getcwd(current_path,sizeof(current_path));
// int ret =
statvfs(current_path, &buffer);
int available = (int)(((double)buffer.f_bavail * (double)buffer.f_bsize) / 1024 / 1024);
uint32_t tt_new_temp = (uint32_t) (((double)Sequences->filesizes)/(1024*1024));
printf("Available disk space in %s: %d %u %llu MB\n",current_path,available,tt_new_temp,Sequences->filesizes); // not working in osx (is that a TODO then?)
max_disk_space = min((uint32_t)available/2, tt_new_temp);
}
if (max_disk_space <= 0) // still 0?
max_disk_space = 10000; // = default for osx
// estimate number of iterations TODO Check if multiplication with totalKmers is actually required or not. It may be just increasing number of partitions for no reason
//uint64_t volume = totalKmers*Sequences->estimate_kmers_volume(smallestKmer); //Since there are totalKmers no of kmers and an upper bound can be estimated by using the smallest size of kmer. Added by Raunaq
uint64_t volume = Sequences->estimate_kmers_volume(smallestKmer); //Since there are totalKmers no of kmers and an upper bound can be estimated by using the smallest size of kmer. Added by Raunaq
uint32_t nb_passes = ( volume / max_disk_space ) + 1;
int passes_hash ;
int nb_threads=1;
#if OMP
use_compressed_reads =true;
nb_threads = 8;
max_memory /= nb_threads;
max_memory = max (max_memory,1);
#endif
// temp bugfix: don't use compressed reads for long reads
if (Sequences->estimate_max_readlen() > 1000000)
use_compressed_reads = false;
uint64_t volume_per_pass,volume_per_partition;
uint32_t nb_partitions;
int partitions_hash;
// loop to lower the number of partitions below the maximum number of simulatenously open files
do
{
volume_per_pass = volume / nb_passes;
nb_partitions = ( volume_per_pass * totalKmers / max_memory ) + 1;
//printf("volume per pass and total volume %llu %llu \n",volume_per_pass,(unsigned long long)volume);
// if partitions are hashed instead of sorted, adjust for load factor
// (as in the worst case, all kmers in the partition are distinct and partition may be slightly bigger due to hash-repartition)
if (use_hashing)
{
nb_partitions = (uint32_t) ceil((float) nb_partitions / load_factor);
nb_partitions = ((nb_partitions * OAHash::size_entry() ) + sizeof(key_type)-1) / sizeof(key_type); // also adjust for hash overhead
}
struct rlimit lim;
int max_open_files = 1000;
int err = getrlimit(RLIMIT_NOFILE, &lim);
if (err == 0)
max_open_files = lim.rlim_cur / 2;
if (nb_partitions >= max_open_files)
nb_passes++;
else
break;
}
while (1);
volume_per_partition= volume_per_pass/nb_partitions;
passes_hash = ceil(log(nb_passes)/log(4));
partitions_hash = ceil(log(nb_partitions)/log(4));
int size_for_reestimation = ceil((passes_hash + partitions_hash)*1.8);
double * lmer_counts = (double * ) malloc(sizeof(long)*pow(4,size_for_reestimation));
long * lmers_for_hash = (long * ) malloc(sizeof(long)*pow(4,size_for_reestimation));
int * partitions_for_lmers =(int * ) malloc(sizeof(int)*pow(4,size_for_reestimation));
Sequences->count_kmers_for_small_value(size_for_reestimation,lmer_counts);
int temp_partition=reestimate_partitions(size_for_reestimation,volume_per_partition,lmer_counts,lmers_for_hash,partitions_for_lmers);
unordered_map<long,int> part_hash;
int total_lmers=pow(4,size_for_reestimation);
for(int it=0;it<total_lmers;it++)
{
pair<long,int> temp_pair(lmers_for_hash[it],partitions_for_lmers[it]);
part_hash.insert (temp_pair); // Add element to the hash
}
//uint64_t up_passes_size = volume_per_pass;
do
{
//recompute the number of partitions based on updated partitions estimate
nb_partitions = ceil(temp_partition*1.0/nb_passes);
struct rlimit lim;
int max_open_files = 1000;
int err = getrlimit(RLIMIT_NOFILE, &lim);
if (err == 0)
max_open_files = lim.rlim_cur / 2;
if (nb_partitions >= max_open_files)
nb_passes++;
else
break;
}while(1);
printf("no of partitions before %lu and after %d passes %lu \n",nb_partitions*nb_passes,temp_partition,nb_passes);
uint64_t total_IO = volume * 2LL * 1024LL*1024LL ;// in bytes + nb_passes * ( volume / (sizeof(kmer_type)*4) ) ; // in bytes
uint64_t temp_IO = 0;
BinaryBankConcurrent * redundant_partitions_file[nb_partitions];
char redundant_filename[nb_partitions][256];
kmer_type kmer;
int max_read_length = KMERSBUFFER_MAX_READLEN;
kmer_type * kmer_table_seq = (kmer_type * ) malloc(sizeof(kmer_type)*max_read_length); ;
kmer_type * kmer_length_table_seq = (kmer_type * ) malloc(sizeof(kmer_type)*max_read_length);
BinaryReads * binread = NULL;
if(use_compressed_reads)
binread = new BinaryReads(return_file_name(binary_read_file),true);
fprintf(stderr,"Sequentially counting ~%llu MB of kmers with %d partition(s) and %d passes using %d thread(s), ~%d MB of memory and ~%d MB of disk space\n", (unsigned long long)volume, nb_partitions,nb_passes, nb_threads, max_memory * nb_threads, max_disk_space);
STARTWALL(count);
mkdir(temp_dir, S_IRWXU | S_IRWXG | S_IROTH | S_IXOTH);
// Open totalKmers files to store counts of totalKmers different k's
BinaryBankConcurrent * SolidKmers[totalKmers];
for (int s=0;s<totalKmers;s++)
{
char temp[1024];
sprintf(temp,"%s.%d",return_file_name(solid_kmers_file),Kmerlist[s]);
uint64_t exp = (((uint64_t)1)<<(Kmerlist[s]*2))-1;
SolidKmers[s] = new BinaryBankConcurrent(temp,sizeof(kmer),true,nb_threads);
//printf("kmer is %d exp is %llu \n",Kmerlist[s],exp);
//BinaryBankConcurrent * SolidKmers = new BinaryBankConcurrent(return_file_name(solid_kmers_file),sizeof(kmer),true,nb_threads);
if (write_count)
{
// write k-mer nbits as the first 4 bytes; and actual k-mer size as the next 4 bits
uint32_t kmer_nbits = sizeof(kmer) * 8;
SolidKmers[s]->write_buffered(&kmer_nbits, 4,0);
SolidKmers[s]->write_buffered(&Kmerlist[s], 4,0);
SolidKmers[s]->flush(0);
}
}
int64_t estimated_NbReads = Sequences->estimate_nb_reads();
char * rseq;
int readlen;
int64_t NbSolid = 0;
int64_t * NbSolid_omp = (int64_t *) calloc(nb_threads,sizeof(int64_t));
//long total_kmers_per_partition[nb_partitions]; //guillaume probably commented it because updating this variable would require synchronization
long distinct_kmers_per_partition[nb_partitions];
uint64_t * histo_count = (uint64_t *) calloc(10001,sizeof(uint64_t));
#if OMP
uint64_t ** histo_count_omp = (uint64_t **) calloc(nb_threads,sizeof(uint64_t *));
for(int ii=0;ii<nb_threads;ii++)
{
histo_count_omp[ii]= (uint64_t *) calloc(10001,sizeof(uint64_t));
}
#endif
//start by the conversion of the file to binary format
if(use_compressed_reads)
{
char * pt_begin;
int idx =0 ;
int64_t NbRead = 0;
Progress progress_conversion;
// progress_conversion.timer_mode=1; // to switch to timer mode (show elapsed and estimated remaining time)
progress_conversion.init(estimated_NbReads,"First step: Converting input file into Binary format");
Sequences->rewind_all();
while(1)
{
if(! Sequences->get_next_seq(&rseq,&readlen)) break; // read original fasta file
if(readlen > max_read_length) // realloc kmer_table_seq if needed
{
max_read_length = 2*readlen;
kmer_table_seq = (kmer_type * ) realloc(kmer_table_seq,sizeof(kmer_type)*max_read_length);
kmer_length_table_seq = (kmer_type * ) realloc(kmer_length_table_seq,sizeof(kmer_type)*max_read_length);
}
pt_begin = rseq;
//should be ok
while (pt_begin < (rseq+ readlen))
{
idx=0; // start a new read
//skips NN
while (*pt_begin =='N' && pt_begin < (rseq+ readlen))
{
pt_begin ++;
}
// goes to next N or end of seq
while ( (pt_begin[idx] !='N') && ((pt_begin +idx) < (rseq+ readlen)) )
{
idx++;
}
//we have a seq beginning at pt_begin of size idx ,without any N, will be treated as a read:
binread->write_read(pt_begin,idx);
revcomp_sequence(pt_begin,idx); // reverse complement the string
binread->write_read(pt_begin,idx); // write reverse complement string
revcomp_sequence(pt_begin,idx); // restore the string
pt_begin += idx;
}
// binread->write_read(rseq,readlen);
NbRead++;
if ((NbRead%10000)==0)
{
progress_conversion.inc(10000);
}
}
//printf("Number of reads converted to binary %d \n",NbRead);
progress_conversion.finish();
binread->close();
}
///fin conversion
if (clear_cache)
{
#ifdef OSX
system("purge");
#else
system("echo 3 > /proc/sys/vm/drop_caches");
#endif
}
#if SINGLE_BAR
Progress progress;
char message[1000];
sprintf(message,"Counting kmers");
progress.timer_mode=1;
if (verbose == 0 )
progress.init(total_IO,message);
#endif
//use_compressed_reads=false; // for testing compute_kmer_from_one_seq
// how many times we will traverse the whole reads file (has an influence on temp disk space)
uint64_t iter_partition=0;
for (uint32_t current_pass = 0; current_pass < nb_passes; current_pass ++)
{
// stop computing if all partitions are done Added by Raunaq
if (iter_partition==temp_partition)
break;
if(use_compressed_reads ) //open binary reads for reading
binread->open(false);
STARTWALL(debpass);
STARTWALL(debw);
int initial_value = current_pass*nb_partitions;
for (uint32_t p=0;p<nb_partitions;p++)
{
sprintf(redundant_filename[p],"%s/partition%d.redundant_kmers",temp_dir,p);
redundant_partitions_file[p] = new BinaryBankConcurrent (redundant_filename[p],sizeof(kmer_type),true, nb_threads);
distinct_kmers_per_partition[p]=0;
}
int final_value = ((current_pass+1)*nb_partitions)-1;
printf("Storing k-mers in partition files between %d and %d \n",initial_value,final_value);
Sequences->rewind_all();
#if !SINGLE_BAR
Progress progress;
progress.timer_mode=1; // to switch to timer mode (show elapsed and estimated remaining time)
char message[1000];
sprintf(message,"Pass %d/%d, Step 1: partitioning",current_pass+1,nb_passes);
if (verbose == 0 )
progress.init(estimated_NbReads,message);
#endif
//current_pass> 0 &&
#if OMP
#pragma omp parallel if(use_compressed_reads) num_threads(nb_threads)
#endif
{
int64_t nbkmers_written =0;
int tid =0;
int64_t NbRead = 0;
int64_t nread =0;
int64_t tempread =0;
long it_zero_wrt =0;
#if OMP
tid = omp_get_thread_num();
#endif
int nreads_in_buffer= 1000;
KmersBuffer * kbuff =NULL;
if(use_compressed_reads)
{
kbuff = new KmersBuffer (binread, 1000000, nreads_in_buffer); //buffer size (in nb of kmers), seq per task // the buffer is per thread
kbuff->binary_read_file = binread->binary_read_file;
}
kmer_type * kmer_table ;
kmer_type * kmer_length_info ; // Added by Raunaq, to store the length of read into the partitions file
while(1)
{
//read the fasta file
if(use_compressed_reads) // && current_pass>0
{
nread = kbuff->readkmers();
if( nread < 0) break;
NbRead+= nread;
tempread+= nread;
}
else
{
if(! Sequences->get_next_seq(&rseq,&readlen)) break; // read original fasta file
if(readlen > max_read_length) // realloc kmer_table_seq if needed
{
max_read_length = 2*readlen;
kmer_table_seq = (kmer_type * ) realloc(kmer_table_seq,sizeof(kmer_type)*max_read_length);
kmer_length_table_seq = (kmer_type * ) realloc(kmer_length_table_seq,sizeof(kmer_type)*max_read_length);
}
}
// if(use_compressed_reads ) //write compressed read file at first pass //&& current_pass==0
// binread->write_read(rseq,readlen);
int i;
int nbkmers =readlen-sizeKmer+1;
if( use_compressed_reads) //current_pass >0 &&
{
nbkmers = kbuff->nkmers;
kmer_table = kbuff->kmers_buffer;
kmer_length_info = kbuff->kmer_length;
}
else //old fashion
{
compute_kmer_table_from_one_seq(readlen,rseq,kmer_table_seq,kmer_length_table_seq,Kmerlist[totalKmers-1]); // Added by Raunaq for computing kmers for all values of k
nbkmers =readlen-Kmerlist[totalKmers-1]+1;
kmer_table = kmer_table_seq;
kmer_length_info = kmer_length_table_seq;
NbRead++;
//printf("Number of kmers read from seq %d \n",nbkmers);
}
nbkmers_written= 0;
char temp_kmer[256];
int zero;
//compute the kmers stored in the buffer kmer_table
for (i=0; i<nbkmers; i++)
{
kmer_type lkmer;
kmer_type lkmer_length;
// kmer = extractKmerFromRead(rseq,i,&graine,&graine_revcomp);
lkmer = kmer_table[i];
lkmer_length = kmer_length_info[i];
// zero = code2seq(lkmer,temp_kmer);
long pass_lkmer = code2first_n_nucleotide(lkmer,size_for_reestimation);
unordered_map<long,int>::const_iterator got = part_hash.find(pass_lkmer);
int p;// compute in which partition this kmer falls into
if(got==part_hash.end())
continue;
else
p = got->second;
// check if this kmer should be included in the current pass
if(!(p >= initial_value && p<= final_value))
continue;
/*
#ifdef _ttmath
(reduced_kmer % nb_partitions).ToInt(p);
#else
p = reduced_kmer % nb_partitions;
#endif
*/
p = p - current_pass*nb_partitions;
nbkmers_written++;
redundant_partitions_file[p]->write_element_buffered(&lkmer,tid); // save this kmer to the right partition file
redundant_partitions_file[p]->write_buffered(&lkmer_length,sizeof(lkmer_length),tid,false); // save the kmer length next to the kmer in the same partition file
// total_kmers_per_partition[p]++; // guillaume probably commented it because updating this variable would require synchronization
}
//NbRead++;
#if SINGLE_BAR
if(verbose==0)
{
if (nb_threads == 1)
progress.inc(nbkmers_written * sizeof(kmer_type));
else
progress.inc(nbkmers_written * sizeof(kmer_type),tid);
}
#endif
// if ((NbRead%10000)==0)
if(tempread> 10000)
{
tempread -= 10000;
if (verbose)
fprintf (stderr,"%cPass %d/%d, loop through reads to separate (redundant) kmers into partitions, processed %lluM reads out of %lluM",13,current_pass+1,nb_passes,(unsigned long long)(NbRead/1000/1000),(unsigned long long)(estimated_NbReads/1000/1000));
#if !SINGLE_BAR
else
if (nb_threads == 1)
progress.set(NbRead);
else
progress.inc(10000,tid);
#endif
}
} //end while
// printf("Count of zero in write is %lu \n",it_zero_wrt);
if(use_compressed_reads)
delete kbuff;
} // end OMP
#if !SINGLE_BAR
if (verbose == 0)
{
if (nb_threads == 1)
progress.finish();
else
progress.finish_threaded(); // here only one thread
sprintf(message,"Pass %d/%d, Step 2: computing kmer count per partition",current_pass+1,nb_passes);
progress.init(nb_partitions+1,message);
}
#endif
if (verbose)fprintf(stderr,"\n");
if (verbose >= 2)
{
STOPWALL(debw,"Writing redundant kmers");
}
STARTWALL(debtri);
for (uint32_t p=0;p<nb_partitions;p++)
{
redundant_partitions_file[p]->close();
redundant_partitions_file[p]->open(false);
}
// for better timing: clear the file cache, since the partitions may still be in memory, that's unfair to low mem machines
if (clear_cache)
{
#ifdef OSX
system("purge");
#else
system("echo 3 > /proc/sys/vm/drop_caches");
#endif
}
//quick and dirty parall with omp, testing
//todo if we want omp and histo : separate histo_count tab per thread that needs to be merged at the end
// TODO to guillaume: remove that todo above, because it is done, right?
kmer_type lkmer,lkmer_length,lkmer_temp,exp;
long it_zero=0;
OAHash * hash;
int p,s;
#if OMP
//omp_set_numthreads(2); //num_threads(2) //if(!output_histo) num_threads(nb_threads)
#pragma omp parallel for private (p,s,lkmer,lkmer_length,hash,lkmer_temp,exp) num_threads(nb_threads)
#endif
// load, sort each partition to output solid kmers
for ( p=0;p<nb_partitions;p++)
{
char temp_kmer[256]; // bug check code
int zero;
kmer_type lkmer_revcomp; // to store revcomps
bool use_hashing_for_this_partition = use_hashing;
if(hybrid_mode)
{
if( (redundant_partitions_file[p]->nb_elements()*sizeof(kmer_type)) < (max_memory*1024LL*1024LL) ) // Maintain totalKmers hash for each partition file
{
use_hashing_for_this_partition = false;
}
else
{
use_hashing_for_this_partition = true;
}
}
int tid =0;
//int s;
//Computing if hashing should be used or not for this partition
#if OMP
tid = omp_get_thread_num();
#endif
//use_hashing_for_this_partition = false; //to check the vector part of the code
if (use_hashing_for_this_partition)
{
// hash partition and save to solid file
hash = new OAHash(max_memory*1024LL*1024LL/2); // One hash to store all types of k-mer lengths
uint64_t nkmers_read=0;
redundant_partitions_file[p]->read_element_buffered(&lkmer_length);
while (redundant_partitions_file[p]->read_element_buffered(&lkmer))
{
if(lkmer_length == Kmerlist[0]) //only add the largest k-mer
hash->increment(lkmer,convert_to_int(lkmer_length));
else
{
unordered_map<int,int>::const_iterator got = kmerlength_map.find(convert_to_int(lkmer_length));
exp = (((kmer_type)1)<<(got->second*2))-1;
lkmer_temp = lkmer & exp;
hash->increment(lkmer_temp,got->second);
}
if(!redundant_partitions_file[p]->read_element_buffered(&lkmer_length))
{
break;
}
nkmers_read++;
#if SINGLE_BAR
if(verbose==0 && nkmers_read==10000)
{
if (nb_threads == 1)
progress.inc(nkmers_read*sizeof(kmer_type));
else
progress.inc(nkmers_read*sizeof(kmer_type),tid);
nkmers_read=0;
}
#endif
}
if (verbose >= 2)
printf("Pass %d/%d partition %d/%d hash load factor: %0.3f\n",current_pass+1,nb_passes,p+1,nb_partitions,hash->load_factor());
for( s=0;s<totalKmers;s++)
{
OAHash * temp_ = new OAHash(max_memory*1024LL*1024LL/2);
hash->start_iterator();
while (hash->next_iterator())
{
uint_abundance_t abundance = hash->iterator->value;
uint_abundance_t abund_tid = (current_pass+1)*100+p;
if(output_histo)
{
uint_abundance_t saturated_abundance;
saturated_abundance = (abundance >= 10000) ? 10000 : abundance;
#if OMP
histo_count_omp[tid][saturated_abundance]++;
#else
histo_count[saturated_abundance]++;
#endif
}
int length_kmer = hash->iterator->length;
lkmer = hash->iterator->key;
if (abundance >= nks && abundance <= max_couv && length_kmer == Kmerlist[s])
{
//write if lkmer is the smaller of it and its reverse complement
lkmer_revcomp = revcomp(lkmer,length_kmer);
if(lkmer < lkmer_revcomp)
{
SolidKmers[s]->write_element_buffered(&(hash->iterator->key),tid);
NbSolid_omp[tid]++;
if (write_count)
SolidKmers[s]->write_buffered(&abundance, sizeof(abundance),tid, false);
}
}
distinct_kmers_per_partition[p]++;
if(s!=totalKmers-1)
{
if(length_kmer == Kmerlist[s])
{
exp = (((kmer_type)1)<<(Kmerlist[s+1]*2))-1;
lkmer_temp = lkmer & exp;
temp_->increment_by_value(lkmer_temp,abundance,Kmerlist[s+1]);
}else {
temp_->increment_by_value(lkmer,abundance,length_kmer);
}
}
}
hash->~OAHash();
hash = temp_;
}
hash->~OAHash();
//printf("All hashes closed and destroyed \n");
}
else
{
// This part does it in slower fashion
// sort partition and save to solid file
//vector < kmer_type > kmers;
vector < kmer_type > kmers[totalKmers];
uint64_t nkmers_read=0;
//int s=0;
redundant_partitions_file[p]->read_element_buffered(&lkmer_length);
while (redundant_partitions_file[p]->read_element_buffered (&lkmer))
{
for(s=0;s<totalKmers;s++)
{
//kmer_type lkmer_temp;
//kmer_type exp;
if(lkmer_length<Kmerlist[s])
continue;
if(s==0)
kmers[s].push_back (lkmer);
else
{
exp = (((kmer_type)1)<<(Kmerlist[s]*2))-1;
lkmer_temp = lkmer & exp; // Converting the kmer to its smaller equivalent in binary
kmers[s].push_back (lkmer_temp);
}
}
nkmers_read++;
if(!redundant_partitions_file[p]->read_element_buffered(&lkmer_length)) break; //Added to get the next length of kmer
#if SINGLE_BAR
if(verbose==0 && nkmers_read==10000)
{
if (nb_threads == 1)
progress.inc(nkmers_read*sizeof(kmer_type));
else
progress.inc(nkmers_read*sizeof(kmer_type),tid);
nkmers_read=0;
}
#endif
}
for(s=0;s<totalKmers;s++)
{
sort (kmers[s].begin (), kmers[s].end ());
kmer_type previous_kmer = *(kmers[s].begin ());
uint_abundance_t abundance = 0;
for (vector < kmer_type >::iterator it = kmers[s].begin (); it != kmers[s].end ();it++)
{
kmer_type current_kmer = *it;
if (current_kmer == previous_kmer)
abundance++;
else
{
if(output_histo)
{
uint_abundance_t saturated_abundance;
saturated_abundance = (abundance >= 10000) ? 10000 : abundance;
#if OMP
histo_count_omp[tid][saturated_abundance]++;
#else
histo_count[saturated_abundance]++;
#endif
}
if (abundance >= nks && abundance <= max_couv)
{
NbSolid_omp[tid]++;
SolidKmers[s]->write_element_buffered(&previous_kmer,tid);
if (write_count)
SolidKmers[s]->write_buffered(&abundance, sizeof(abundance),tid, false);
}
abundance = 1;
distinct_kmers_per_partition[p]++;
}
previous_kmer = current_kmer;
}
//last kmer
distinct_kmers_per_partition[p]++;
if(output_histo)
{
uint_abundance_t saturated_abundance;
saturated_abundance = (abundance >= 10000) ? 10000 : abundance;
#if OMP
histo_count_omp[tid][saturated_abundance]++;
#else
histo_count[saturated_abundance]++;
#endif
}
if (abundance >= nks && abundance <= max_couv)
{
NbSolid_omp[tid]++;
SolidKmers[s]->write_element_buffered(&previous_kmer,tid);
if (write_count)
SolidKmers[s]->write_buffered(&abundance, sizeof(abundance),tid, false);
}
}
}
//printf("Done writing kmers for all K \n");
if (verbose >= 1)
fprintf(stderr,"%cPass %d/%d, loaded and sorted partition %d/%d, found %lld solid kmers so far",13,current_pass+1,nb_passes,p+1,nb_partitions,(long long)(NbSolid_omp[tid]));
//printf("Done writing kmers for all K %d check 1 \n",p);
if (verbose >= 2)
printf("\nPass %d/%d partition %d/%d %ld distinct kmers\n",current_pass+1,nb_passes,p+1,nb_partitions,/*total_kmers_per_partition[p],*/distinct_kmers_per_partition[p]);
#if !SINGLE_BAR
if (verbose == 0 && nb_threads==1)
progress.inc(1);
else if (verbose == 0 && nb_threads>1)
progress.inc(1,tid);
#endif
//if(redundant_partitions_file[p]->find_error()) {
// printf("Error in the binary file \n");
//}
redundant_partitions_file[p]->close();
remove(redundant_filename[p]);
} // end for partitions
#if OMP
//merge histo
if(output_histo)
{
for (int cc=1; cc<10001; cc++) {
uint64_t sum_omp = 0;
for(int ii=0;ii<nb_threads;ii++)
{
sum_omp += histo_count_omp[ii][cc];
}
histo_count[cc] = sum_omp;
}
}
#endif
#if !SINGLE_BAR
if (verbose == 0 && nb_threads == 1)
progress.finish();
else if (verbose == 0 && nb_threads > 1 )
progress.finish_threaded();
#endif
if (verbose) fprintf(stderr,"\n");
if (verbose >= 2)
{
STOPWALL(debtri,"Reading and sorting partitions");
STOPWALL(debpass,"Pass total");
}
//printf("Done writing kmers for all K check 4 \n");
if(use_compressed_reads)
binread->close();
//delete
for (uint32_t p=0;p<nb_partitions;p++)
{
delete redundant_partitions_file[p] ;
}
}
//printf("Done writing kmers for all K check 5 \n");
//single bar
#if SINGLE_BAR
if (verbose == 0 && nb_threads == 1)
progress.finish();
else if (verbose == 0 && nb_threads > 1 )
progress.finish_threaded();
#endif
if(output_histo)
{
FILE * histo_file = fopen(return_file_name(histo_file_name),"w");
for (int cc=1; cc<10001; cc++) {
fprintf(histo_file,"%i\t%llu\n",cc,(unsigned long long)(histo_count[cc]));
}
fclose(histo_file);
}
free(histo_count);
NbSolid = NbSolid_omp[0];
#if OMP
NbSolid=0;
for(int ii=0;ii<nb_threads;ii++)
{
NbSolid += NbSolid_omp[ii];
}
#endif
for ( int s=0;s<totalKmers;s++)
SolidKmers[s]->close();
printf("\nSaved %lld solid kmers\n",(long long)NbSolid);
rmdir(temp_dir);
STOPWALL(count,"Counted kmers");
fprintf(stderr,"\n------------------ Counted kmers and kept those with abundance >=%i, \n",nks);
}
